Extracts from the fungus Guignardia sp., their uses in pharmaceutical compositions, new isolate compound from the extract of the fungus Gignardia sp. and its use in pharmaceutical compositions

ABSTRACT

The present invention refers to extracts from the fungus Guignardia sp., and also a new isolate compound from the aforementioned extract, both having antimicrobial activities, particularly antibacterial and antifungal activities, and their use in pharmaceutical compositions. The new compound, isolated from the extract of the fungus Guignardia sp., presents a dioxolanone ring, having the following formula:

[0001] The present invention refers to extracts from the fungus Guignardia sp., and also a new isolate compound from the aforementioned extract, both having antimicrobial activities, particularly antibacterial and antifungal activities, and their use in pharmaceutical compositions.

[0002] The new compound, isolated from the extract of the fungus Guignardia sp., presents a dioxolanone ring, having the following formula:

BACKGROUND OF THE INVENTION

[0003] The search for extracts obtained from plants, protista, fungi or animals and isolated molecules, identified and characterised from these extracts, having antimicrobial activities, has become one of the main motivators for the research and development of new drugs providing a larger scope of action and less toxicity. Furthermore, various pathogens that infect both animals and human beings are becoming resistant to many of the drugs presently in use which heightens the interest for new molecules.

[0004] After the major development of synthetic drugs that marked the second half of the 20th century, the nineties stand out as the era of research for drugs based on active principles obtained or isolated from natural products. The use of medicinal plants, protista, fungi and animals as raw material for isolating pure natural products, or for the obtainment of extracts and/or the formulation of phytotherapeutic products, consists an integral part of modern therapeutics.

[0005] The publications of natural products listed in Chemical Abstracts between 1985 and 1995 show that 21.1% were made by Japan, 10% by the US, another 10% by China, 8% by Germany, 8% by India, 4% by France and only 1.6% were contributed by Brazil (Gottlieb, O. R. “Natural products research in Brazil.” Ciência e Cultura. Journal of the Brazilian Association for the Advancement of Science. 49. (5, 6). 315-320. 1997).

[0006] Through the years, natural products have formed the basis for the treatment of illnesses of all the ancient cultures and continue to be the main source of primary health treatment for 80% of the world population. Sophisticated systems of traditional medicine have existed for thousands of years in many countries, such as China and India. Medicinal plants, protista, fungi and animals are also extensively used in the traditional systems of African medicine. Many phytodrugs are used in Europe and the US. Numerous examples of well known active principles derived from natural products can be cited, such as, for example, from plants: glycosides for the treatment of heart diseases obtained from Digitalis purpurea L.; the antihypertensive and tranquilliser reserpine, derived from the Rauvolfia serpentina (L.); quinine, antimalarial agent, from the Cinchona ssp.; the opiatic analgesics codeine and morphine from the Papaver somniferum L.; the antileucemic agents Vinblastine and Vincristine, from the Catharanthus roseus (L.) (see Baker, J. T., Borris, R. P., Carté, B., Cordell, G. A., Soejarto, D. D., Cragg, G. M., Gupta, M. P., Iwu, M. M., Madulid, D. R. and Tyler, V. E. “Natural product drug discovery and development: New perspectives on international collaboration”. Journal of Natural Products. 58 (9), 1325-1357. 1995).

[0007] South America is becoming the focal point of much research in the field of natural products because it is considered one of the largest centres of biodiversity. South America is the continent of origin of many plants, Protista, fungi and animals that have already furnished—or demonstrate the potential to furnish—important products used in drugs.

[0008] As an example of the attempt to find natural molecules capable of acting against infectious agents, various efforts have been made, for example, to isolate and characterise at molecular level, a broad band of natural peptidic antimicrobial components obtained from animals (amphibians, frogs, mammals, insects), plants, fungi and bacterial species (Hanckoc et al., 1995). These biologically active peptides vary as to the scope of activity, mode of action, molecular weight (from 1.1 to more than 10 kDa), genetic origin and biochemical properties.

[0009] Various programs with the objective of identifying metabolites in extracts from fungi are also under way. Ganoderma pfeifferi Bres. (synonimous Ganoderma cupreolaccatum Kalchbr., Ganoderma soniese Steyaert) is a basidiomycete found only in Europe, and which lives on Fagus and various other trees such as Aesculus, Acer, Fraxinus, Prunus and Quercus. This species of basidiomycete is distinguishable from other older species such as Ganoderma lucidum and Ganoderma resinaceum by its dark brown context. Ganoderma pfeifferi is one of the lesser known species of the Ganodermaceteae family from the phytochemical investigation point of view. However, a reasonable number of triterpenes, polysaccharides and steroids, with interesting biological and pharmacological activities, have been isolated from the extracts of G. lucidum and G. applanatum.

[0010] Mothana et al (Mothana, R. A. A., Jansen, R., Jülich, W. and Lindequist, U. “Ganomycins A and B, new antimicrobial farnesyl hydroquinones from the basidiomycete Ganoderma pfeifferi. J. Nat. Prod., 63. 416-418. 2000) isolated and elucidated the structure of two hydroquinones obtained from the extract of the dichloromethane of G. pfeifferi. These compounds (i) acid 2-[2-(2.5 dihydroxyphenyl)-ethylidene]-11-hydroxy-6.10-dimythyl-undeca-5.9-dienic and (ii) acid acid 2-[2-(2.5 dihydroxyphenyl)-ethylidene]-6.10-dimythyl-undeca-5.9-dienic present antibacterial activity.

[0011] Marine fungi have also been cited as potential sources of active secondary metabolites of biological and chemical interest for the development of new pharmaceutical compositions. Afiyatullov et al (Afiyatullov, S. S., Kuznetsova, T. A., Isakov, V.V., Pivkin, M. V., Prokofeva, N. G., Elyakov, G. B.. “New Diterpenic Atrosides of the fungus Acremonium striatisporum isolated from a Sea Cucumber. J. Nat. Prod. 63.848.-850.2000)] investigated the fungus Acremonium striatisporum isolated from the sea cucumber Eupentacta fraudatrix. The authors isolated and characterised two new diterpenic glycosides from this fungus (named virescinosides M and N) also isolating, furthermore, three known compounds (virescinosides A, B and C). These compounds presented cytotoxic effects on the eggs of the Strongylocentrotus intermedius during initial stages of development (MIC₅₀=2.7-20 μM) and also demonstrated cytotoxic activity, in vitro, against tumorous cells of Ehrlich's carcinoma (IC50=10-100μM).

[0012] Furthermore, various other examples can be cited concerning the obtainment of extracts resulting from the fermentation of fungi and/or molecules obtained from these when showing interesting biological activity, amongst others, against human cytomegalovirus (Guo, B., Daí, J. R., Ng, S., Huang, Y., Leong, C., Ong, W. e Carté, B. “Cytonic Acids A and B: novel tridepside inhibitors of hCMV protease from Endophytic fungus Cytonaema species. J. Nat. Prod. 63.602-604-2000).

[0013] The U.S. Pat. No. 3,891,506 describes a substance, named quintomycin, with potential use as an antibiotic which is produced by the fungus Streptomyces lividus.

[0014] Concerning the fungus belonging to the genus Guignardia, it is possible to cite the obtainment of alkaline lipolitic enzymes isolated from this micro-organism, in particular from G. laricina and G. paulowniae, and its uses in detergents (see U.S. Pat. No. 5,919,746).

[0015] Despite being quite vast, medical knowledge still remains incomplete as to the fight against pathogenic micro-organisms having already infected the human organism, especially those originating from (i) nosocomial infections where the aerobiological micro-organisms constitute, for example, an important vector, (ii) food poisoning and (iii) the contamination of water. Furthermore, such micro-organisms may also become resistant to any known drug, even the latest generation ones, due to their possible biological mutations.

[0016] In this context, the development of new, more efficient drugs for the treatment of infections caused by these micro-organisms becomes urgent, especially bacteria and fungi, with the capability of having effect in cases where many strains have already become resistant to the drugs commonly employed and commercially available. In this sense, the search for natural extracts obtained from animals (amphibians, frogs, mammals, insects), plants, fungi and bacteria species has shown to be an interesting alternative to attend to the demand for more efficient drugs with lower toxicity to treat patients with generalised infections, caused by infection through fungi and bacteria, and which are common, for example, in hospital environments.

SUMMARY OF THE INVENTION

[0017] One of the purposes of the present invention is to provide extracts obtained from the fermentation of the fungus Guignardia sp.

[0018] Another purpose of the present invention is to provide, from the aforementioned extract of the fungus Guignardia sp., a new molecule containing a dioxolanone ring, or a salt of the same, having the following formula:

[0019] A first embodiment of the following invention relates to a pharmaceutical composition including the extract resulting from the fermentation of the fungus Guignardia sp. combined with a pharmaceutically acceptable vehicle.

[0020] A second embodiment of the present invention refers to a pharmaceutical composition including the molecule (Z)′-5-benzylidene-2-isopropyl-4-oxo-1.3-dioxolane-2-carboxyl acid or a salt of the same combined with a pharmaceutically acceptable vehicle.

BRIEF DESCRIPTION OF THE DIAGRAMS

[0021]FIG. 1 represents the structure of the new compound of the invention (Z)-5-benzylidene-2-isopropyl-4-oxo-1.3-dioxolane-2-carboxyl acid and its numbering in accordance with the data of Table 1.

[0022]FIG. 2 shows the spectrum of circular Dichroism (CD)

DETAILED DESCRIPTION OF THE INVENTION

[0023] The extract of the fungus GUIGNARDIA SP.

[0024] The search for endophytic fungi in plants normally employed in traditional medicine has resulted in various studies. In the case of the present invention the facultative tree Spondias mombin L. (Anacardiaceae), common name Yellow Mombin (or Hog Plum), with a height varying between 20 and 25 meters is a species normally encountered in neotropical regions and with great diversity in the northern Amazonia and the Brazilian Atlantic forest. It became an important tree in an economic aspect, principally in Amazonia and north-eastern Brazil, due to its edible fruit. Furthermore, the recent isolation of compounds with medicinal properties from the leaves of S. mombin has contributed to the increase of research concerning the chemical composition of its natural products (Corthout, J., Pieters, L., Claeys, M., Vanden Berghe, D. A. e Vlietinck, A. J. “Antiviral ellagitannins from S. mombim”-Phytochemistry.30. 1129-1130. 1991).

[0025] The diversity of the rate of endophytes detected from the plants that grow in tropical regions along with their potential role and the use of these fungi have been discussed by various authors. Much of the research concerning endophytic fungi has shown that a series of biotic and abiotic factors may influence the composition of the groups of fungus (Stone, J. and Petrini, O. Endophytes of forest trees: a model for Fungus-Plant Interactions. pp.129-140. In: The Mycota V, Part B. Eds. Carroll and Tudzynski. Springer-Verlag, Berlin. 1997). For example, it has been demonstrated that a fungus shows a preference for colonising determined plant tissues, also that normally isolated rages have shown in a consistent manner differences of frequency between organs. Petrini (Fungal endophytes of tree leaves. pp. 179-197. In: Microbial Ecology of leaves. Eds. Andrews, J. H., Hirano, S. S. Springer Verlag. 1991) has discussed the tissue and organ specificity shown by endophytic fungi as a result of the adaptation to the different physiological conditions of the plant.

[0026] The fungus Guignardia (Ascomycota) whose extracts are to be the object of the present invention was obtained as endophyte from the aerial part of the trees of the genus Spondias (Anacardiaceae) or closely related genera. The aerial parts are sterilised employing adequate alcoholic solvents including, but not limited to methanol, ethanol, 1-propenol, 2-propenol, iso-butanol, sec-butanol, posterior addition of a chlorine based agent, for example sodium hypochlorite, peracetic acid, HgCl₂, amongst others to the knowledge of those versed in the matter, and a wash with one of the aforementioned solvents. The aerial parts in the forms of disks were placed in Petri dishes with an agar medium, containing sources of carbon and nitrogen to the knowledge of those versed in the matter, supplemented with an antibiotic such as, for example, streptomycin or chloramphenicol, amongst others and incubated at ambient temperature. Each colony was then isolated and identified.

[0027] Once the fungus isolated, the extract of the same is obtained after fermentation, through the following sequences:

[0028] (a) Flasks containing an appropriate volume of medium containing sources of carbon and nitrogen, such as starch, glucose, glycerol, maltose, fructose, dextrine, galactose, peptone, meat extracts, ammonia salts, inorganic nitrate amongst others to the knowledge of those versed in the matter, are inoculated in aseptic conditions.

[0029] (b) The cultures are then incubated at ambient temperature and placed in a rotative agitator at approximately 110 rotations per minute (rpm).

[0030] (c) After fermentation, for an appropriate period of time, employing conditions to the knowledge of those versed in the matter the filtrate is then extracted with an organic solvent which, in this case may include, but is not limited to hexane, cyclohexane, ethyl acetate, dichloromethane, methanol or ethanol.

[0031] (d) The concentrated organic raw extracts may be obtained by evaporation under vacuum until dry. Dehydration is recommended in the case an aqueous raw extract is required, for example, through lyophilisation or dry aspersion.

[0032] As demonstrated previously the extracts of the present invention can be obtained by known processes.

[0033] The raw extracts may be used directly in the pharmaceutical formulations of the present invention or, alternatively, may be purified by appropriate methods as previously mentioned, such as, for example, fractionation by column chromatography, obtaining fractions with biological activity.

[0034] The obtainment of the new compound

[0035] Once the extracts obtained, in accordance with the sequences described above, the obtainment of the new compound of the present invention (Z)-5-benzylidene-2-isopropyl-4-oxo-1.3-dioxolane-2-carboxyl acid or, simply, guignardic acid can be undertaken through the purification of the extract, obtained in (d) above, with appropriate techniques such as, for example, thin layer chromatography and high resolution liquid chromatography.

[0036] The pharmaceutical compositions

[0037] The pharmaceutical compositions containing the raw extracts of Guignardia of the present invention, and also the new compound, can be administered through the digestive tract (orally or through the use of suppositories), or by parenteral or cutaneous means. The vehicles employed are known to those versed in the techniques.

[0038] For oral administration, the drug may be in the form of tablets, pills, capsules or in the form of solutions or suspensions. The solid compositions contain the active ingredient mixed with non-toxic excipients appropriate for the manufacture of tablets, such as starch, milk derived sugars, certain types of carbonates and/or bicarbonates, phosphates etc. The tablets may be coated or not, depending on the location where the disintegration and absorption of the drug should occur in the gastro-intestinal tract. In the cases of aqueous suspensions or solutions, excipients such as methyl cellulose, sodium alginate, gum arabic, lecithin etc. may be used with one or more additives, such as preservatives, colourants, flavours, thickeners, etc.

[0039] The quantity of the extract to be combined with the pharmaceutically acceptable vehicle in a manner as to produce the appropriate form of dose will depend on the organism to be treated and the method of administration selected. However, in the case of the present invention the pharmaceutical compositions may contain, preferentially, the extract of Guignardia in a quantity varying from 1 to 50% in weight, for use in the treatment of infections caused by filamentous fungi, yeasts, bacteria and actinomycetes.

[0040] The quantity of the compound (Z)-5-benzylidene-2-isopropyl-4-oxo-1.3-dioxolane-2-carboxyl acid or its salt to be combined with the pharmaceutically acceptable vehicle in a manner as to produce the appropriate form of dose will depend on the organism to be treated and the method of administration selected. However, in the case of the present invention the pharmaceutical compositions, may contain, preferentially, the aforementioned compound or its salt in a quantity varying from 1 to 50% in weight, for use in the treatment of infections caused by fungi or bacteria.

[0041] It must be understood that the specific level of the dose for any given patient will depend on a variety of factors including the activity of the specific compound employed, age, body weight, overall clinical condition, sex, diet, time and method of administration, rate of excretion, combination with other drugs and the severity of the illness to be treated.

[0042] The present invention is described in detail through the examples presented below. It is necessary to point out that the invention is not limited to these examples but also includes variations and modifications within the scope of which it functions.

EXAMPLE 1: ISOLATING THE FUNGUS

[0043] Guignardia sp. (Ascomycota) was isolated as an endophyte from the sterilised surface of the leaves of the tree Spondias mombin L. (Anacardiaceae) collected in Rio de Janeiro. The leaves were sterilised within 24 hours after collection through the immersion of these in ethanol at 75% during 1 minute, followed by the addition of sodium hypochlorite with analytic purity (0-12% of chlorine) during 5 minutes and then washed with ethanol at 75% for 0.5 minutes. Leaves in the form of disks with a diameter of approximately 3 mm were mounted in groups of five on Petri dishes containing cornflour agar with dextrose (CMD, Difco) supplemented with 4 g/l of streptomycin sulphate. The plaques were incubated at 22° C. Each colony was isolated for later identification through the transfer of the mycelium to a medium of cornflour agar with dextrose and/or 2% extract of malt agar (Difco). Stock cultures of Guignardia sp. were maintained in inclined tubes containing cornflour agar medium (Difco) at a temperature of 4° C.

EXAMPLE 2: CONDITIONS FOR CULTURE AND EXTRACTION

[0044] Erlenmeyer flasks (250 ml) containing 50 ml of malt extract broth(20 g/l of malt extract, 1 g/l of peptone and 20 g/l of glucose) per flask were inoculated under aseptic conditions. The cultures were incubated at ambient temperature and placed in a rotative agitator (110 rpm). After fermentation in malt extract for 14 days the filtrate is removed (pH=4.5) and undergoes an extraction with ethyl acetate and posterior evaporation, under vacuum, until dry, obtaining 57.6 mg of raw extract.

EXAMPLE 3: RETENTION TIME DATA AND λ_(MAX) OF THE PRINCIPAL PEAKS DETECTED IN THE EXTRACTS OF GIUGNARDIA SP.

[0045] These results were obtained by high resolution liquid chromatography using conditions that are to the knowledge of those versed in the matter. Tissue of Retention Wavelength Taxon plant Locality time (min) (nm) Guignardia sp. Leaf Rio de 5.4 225 Janeiro 8.3 225, 275 9.6 225sh, 305, 320sh 10.6 225sh, 305, 320sh 17.0 265

EXAMPLE 4: BIOLOGICAL ACTIVITY OF THE GUIGNARDIA SP. EXTRACT

[0046] The tests for the biological activity of the raw extract obtained in EXAMPLE 2 above were undertaken employing no more than routine methodology that is to the knowledge of those versed in the matter.

[0047] As a result of an initial scan of the raw extract of Guignardia sp. and using a test on calibration plaques strong inhibition was verified on the following micro-organisms: Actino sp. (Gram positive filamentous bacteria), Escherichia coli (Gram negative bacteria), Staphylococcus aureus (Gram positive bacteria), Saccharomyces cerevisae (yeast), Geotrichum sp. (filamentous fungus), Penecillium canadensis (filamentous fungus). TABLE 1 Biological activity demonstrated by the raw extract of Guignardia sp. fungus Actinomycete bacteria Yeast Filamentous Taxon ACT ESC STA SAC GEO PCA Guignardia sp. 1 1 1 1 1 1

EXAMPLE 5: ISOLATION OF THE COMPOUND

[0048] The purification was undertaken by the separation of the extract employing fine layer chromatography (silica gel, CHCl₃:MeOH:NH₄OH(25%), in the following proportions 78:19:3, respectively). Eight active bands in ultraviolet were generated from the plaques and eluated with MeOH:CHCl₃ in the proportion of 8:2, respectively. The guignardic acid compound was isolated from the fraction 2 (R_(f): 0.2) that presented elevated bioactivity by a semipreparative high resolution liquid chromatography: column C₈ nucleosil (7 μm, 10×250 mm; Macherey-Nagel, Oensingen, Switzerland); flow rate of 5 ml min⁻¹, solvent system: A=H₂O and B=MeOH with a linear gradient varying from 100% of the solvent A to 100% of the solvent B in 20 minutes, followed by passing the solvent B at 100% for 5 minutes. Through this procedure it is possible to obtain 12 mg of the guignardic acid compound.

EXAMPLE 6: CHARACTERISATION OF GUIGNARDIC ACID

[0049] The official name of the compound according to the IUPAC nomenclature is (Z)-5-benzylidene-2-isopropyl-4-oxo-1.3-dioxolane-2-carboxyl acid and its structure is shown in FIG. 1. The elucidation of its structure was done using a combination of the methods of Nuclear Magnetic Resonance (NMR) in 1D and 2D [¹H, ¹³C Distortionless Enhancement by Polarisation Transfer—DEPT, ¹H, ¹³C COSY (Correlated Spectroscopy), HMQC (a modern inverse version of experiment C, H-COSY that shows the correlations ¹J-C, H) and HMBC (Heternuclear Multiple Bonding Correlation)], ultraviolet, infrared, mass spectroscopy and CD Spectrum (circular dichroism).

[0050] Not only the NMR spectrum of the ¹³C and the DEPT, but also the HMQC and HMBC experiments in dimethyl sulphoxide (d⁶-DMSO) allowed the detection of 14 carbon atoms, including two carbonyls (δ_(C) 166.5 and 164.6), an olefinic methyne (δ_(C) 104.0/δ_(H) 6.22), two carbon quaternaries (one olefinic in δ_(C) 139.1 and one in δ_(C) 111.1, that indicate the presence of an acetal group, as well as a methyne (δ_(C) 31.5/δ_(H) 2.62)and two methyl groups (δ_(C) 16.4/δ_(C) 15.1). Typical signs of a monosubstituted phenyl ring are also encountered in the NMR spectrum of the ¹³C.

[0051] The NMR spectrum of ¹H presented a doublet in δ_(H) 7.66 (2H) and two triplets in δ_(H) 7.38 (2H) and δ_(H) 7.27 (1H) also attributed to the monosubstituted phenyl ring. A simplex in δ_(H) (1H) shows an olefinic proton. The signal in δ_(H) 2.62 shows a septet which jointly with two doublets in δ_(H) 0.92 and δ_(H) 0.95, identify an isopropyl group (data from the NMR spectrum of the ¹³C and the ¹H compound of the present invention are detailed in Table 2 in consonance with FIG. 1).

[0052] Table 2: Data from the NMR spectrum of the ¹³C and the ¹H in consonance with the numbering shown in FIG. 1). C/H δ_(H) ppm δ_(c) ppm 16 166.5(s) —  4 164.6(s) —  5 139.1(s) —  2 111.0(s) —  7 133.3(s) — 8 + 12 129.1(d) 7.66(2H, t, J = 7.4 Hz) 9 + 11 128.8(d) 7.38(2H, t, J = 7.7 Hz) 10 128.1(d) 7.27(1H, t, J = 7.4 Hz)  6 104.0(d) 6.22(1H, s) 13  31.6(d) 2.62(1H, sept., J = 6.8 Hz) 14  15.1(q) 0.92(3H, d.; J = 6.9 Hz) 15  16.4(q) 0.95(3H, d., J = 6.9 Hz)

[0053] Two carbonyls and four double bonds are responsible for the presence of 6 saturations. Two remaining levels of saturation suggest that the compound possesses two rings, with one of them being the monosubstituted phenyl ring.

[0054] Guignardic acid (GA) from the data of the electrospray of the mass spectroscopy presented the molecular weight of 262 m/z undertaken in a Finnigan TSQ 700 spectrometer equipped with an atmospheric pressure chemical ionisation source (APCI) . The molecular weight of guignardic acid was obtained through ES-MS in negative mode. The ES-MS showed the molecular ion as [M—H]⁻ at m/z 261 which indicates the molecular weight at 262, indicating thus, an identical number or absence of nitrogen. The mass spectrum in tandem (MS/MS)of the parental ion in 261 m/z presented two significant products: (i)one in 217 m/z, which was originated by the loss of a carboxyl group such as CO² and (ii)another in 189 m/z, which is the principal fragmentation ion and can be described as [M—H—CO²—CO]⁻.

[0055] The molecular formula C¹⁴H¹⁴O⁵ was deduced from the number of protons and atoms of carbon found in the NMR spectrum of ¹H and ¹³C, combined with the mass spectrum. The ultraviolet spectrum in MeOH of the compound of the invention showed an absorption at λ_(max) in 301 and 225 sh nm, suggesting a chromophore system and which provides evidence that the double exocyclic bond is configured as (Z) (Hans-Joachim Brunk et al. Chem. Ber.116. 2165-2172. 1983; Ramage, R. et al. J. Chem. Soc. Perkin Trans. I.1531.1984).

[0056] The infrared spectrum was measured in a Perkin Elmer 297 type spectrometer and presented the following data in cm: ν_(max) (CHC13) 3404br, 3109w, 3068w, 2992m, 2962m, 2879w, 2837w, 1783s, 1666s, 1646w, 1495w, 1450w, 1400w 2360m, 1339w, 1320w, 1301w, 1273w, 1182w, 1167w, 1152w, 1094m, 1059w, 1009m, 974w, 958w, 917w, 881w, 862w, 823w.

[0057] The ample vibration starting with OH at 3404 cm⁻¹, together with a strong absorption of C═O at 1666 cm⁻¹ shows evidence of an acid group. Lactones composed by a 5 member ring at 1783 cm⁻¹ appear as a result of the absorption of a C═O group. Two C═C conjugated with an aromatic ring and with C═O at 1646 cm⁻¹ were also detected.

[0058] The value of the optical rotation of guignardic acid is [α]²⁰D=56.5 (c 0.2 EtOAc) showing that this compound is quiral. The exact quirality in the quiral centre is not known at the present moment, however there is confirmation through the optical rotation and from the CD spectrum demonstrated in FIG. 2.

EXAMPLE 7: BIOLOGICAL ACTIVITY OF THE COMPOUND (Z)-5-benzylidene-2-isopropyl-4-oxo-1.3-dioxolane-2-carboxyl acid (GUIGNARDIC ACID).

[0059] Guided fractionation of the bioactivity of the extract of ethyl acetate (obtained in EXAMPLE 2 above) resulted in the isolation of the new optically active guignardic acid compound. The antimicrobial activity of this compound was detected employing the bioautographical method on a layer of agar (Rahalison, L.; Hamburger, M., Hostettmann, K.; Monod, M.; Frenk, E. Phytochemical Ananlysis.2.199-203.1991). The following micro-organisms were tested: Escherichia coli (ATCC 25922) and Staphylococcus aureus (ATCC 25923). The medium used was the Mueller-Hinton in agar (Oxoid). The cultures grew during the night in nutrient medium broth number 3 (Fluka). For the bioautographic test the cultures were standardised through successive dilutions in 10⁵ cells/ml. The plaques were incubated at 37° C. for a period of 24 hours, sprayed with an aqueous solution of Methylthiazolyltetrazolium chloride (MTT) at 0.25% and then incubated for a further two hours at 37° C. The active fractions were detected under the form of white areas of inhibition on a lilac background.

[0060] The antibacterial activity verified for the compound of the invention was of 1.5×10⁻⁷ molar against E. coli and 0.75×10⁻⁷ molar against S. aureus. 

1. Aqueous raw extract or organic raw extract with pharmacological activity characterised by the fact of being obtained from an aqueous or organic solvent extraction of the filtrate, which is removed from the fermentation of the fungus Guignardia.
 2. Raw extract in accordance with claim 1 characterised by the fact that the fungus is the Guignardia sp.
 3. Aqueous raw extract in accordance with claim 2 characterised by the fact that the same is lyophilised.
 4. Organic raw extract in accordance with claim 2 characterised by the fact that the extraction occurs with an organic solvent selected from the group consisting of hexane, cyclohexane, ethyl acetate, dichloromethane, methanol or ethanol.
 5. Organic raw extract in accordance with claim 4 characterised by the fact that the extraction occurs with ethyl acetate.
 6. Organic raw extract in accordance with claim 1 characterised by the fact of presenting activity against infections caused by fungi and bacteria.
 7. Pharmaceutical composition characterised by possessing as active ingredient an efficient quantity of the raw extract in accordance with claim 1 and a pharmaceutically acceptable vehicle.
 8. Pharmaceutical composition in accordance with claim 7 characterised by being used in the treatment of microbial infections, preferentially in the treatment of illnesses caused by filamentous fungi, yeasts, actynomycetes and bacteria.
 9. Pharmaceutical composition in accordance with claim 8 characterised by the fact of being used in the treatment of infections caused by Gram negative bacteria.
 10. Pharmaceutical composition in accordance with claim 9 characterised by the fact that the bacteria is the Escherichia coli.
 11. Pharmaceutical composition in accordance with claim 8 characterised by the fact of being used in the treatment of infections caused by Gram positive bacteria.
 12. Pharmaceutical composition in accordance with claim 11 characterised by the fact that the bacteria is the Staphylococcus aureus.
 13. Pharmaceutical composition in accordance with claim 8 characterised by the fact of being used in the treatment of infections caused by filamentous fungi.
 14. Pharmaceutical composition in accordance with claim 13 characterised by the fact that the fungi are the Geotrichum sp. or the Penicillium canadensis.
 15. Pharmaceutical composition in accordance with claim 8 characterised by the fact of being used in the treatment of infections caused by actinomycetes.
 16. Pharmaceutical composition in accordance with claim 15 characterised by the fact that the actinomycete is the Actyno sp.
 17. Pharmaceutical composition in accordance with claim 8 characterised by the fact that the active ingredient is present in a quantity varying between 1 and 50% in weight.
 18. Compound characterised by possessing the formula:

or a pharmaceutically acceptable salt of the same.
 19. Pharmaceutical composition characterised by including as active ingredient an efficient quantity of the compound in accordance with claim 18 and a pharmaceutically acceptable vehicle.
 20. Pharmaceutical composition in accordance with claim 19 characterised by being used in the treatment of microbial infections, preferentially in the treatment of illnesses caused by fungi and bacteria.
 21. Pharmaceutical composition in accordance with claim 20 characterised by the fact of being used in the treatment of infections caused by Gram negative bacteria.
 22. Pharmaceutical composition in accordance with claim 21 characterised by the fact that the bacteria is the Escherichia coli.
 23. Pharmaceutical composition in accordance with claim 20 characterised by the fact of being used in the treatment of infections caused by Gram positive bacteria.
 24. Pharmaceutical composition in accordance with claim 23 characterised by the fact that the bacteria is the Staphylococcus aureus.
 25. Pharmaceutical composition in accordance with claim 21 characterised by the fact that the active ingredient is present in a quantity varying between 1 and 50% in weight. 